Light emission reducing compounds for electronic devices

ABSTRACT

Double-notch filters for electronic devices are provided that filter light from both the blue spectrum as well as the red spectrum in narrow wavelength bands, or “notches.” A double-notch filter can, using input light from a conventional LED-backlit LCD display, output light that can be measured as substantially satisfying criteria for a D65 white point. In some examples, a double-notch filter can output light that can be measured as nearly satisfying criteria for a D65 white point, to within +/− 500 Kelvin. In some examples, a double-notch filter can output light that can be measured as nearly satisfying criteria for a D65 white point, to within +/− 1000 Kelvin.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation-in-part of U.S. Nonprovisional application Ser. No. 14/719,604, filed May 22, 2015 and titled LIGHT EMISSION REDUCING FILM FOR ELECTRONIC DEVICES, which claims the benefit of U.S. Provisional Application No. 62/002,412, filed May 23, 2014 and titled LIGHT EMISSION REDUCING FILM FOR ELECTRONIC DEVICES. This application claims the benefit of U.S. Provisional Application No. 62/421,578, filed Nov. 14, 2016 and titled LIGHT EMISSION REDUCING COMPOUNDS FOR ELECTRONIC DEVICES.

This application is related to U.S. Provisional Application No. 62/175,926, filed Jun. 15, 2015 and titled LIGHT EMISSION REDUCING FILM FOR ELECTRONIC DEVICES, U.S. Provisional Application No. 62/254,871, filed Nov. 13, 2015 and titled LIGHT EMISSION REDUCING COMPOUNDS FOR ELECTRONIC DEVICES, U.S. Provisional Application No. 62/255,287, filed Nov. 13, 2015 and titled LIGHT EMISSION REDUCING FILM FOR VIRTUAL REALITY HEADSET, U.S. Provisional Application No. 62/322,624, filed Apr. 14, 2016 and titled LIGHT EMISSION REDUCING FILM FOR ELECTRONIC DEVICES, International Application under the Patent Cooperation Treaty No. PCT/US2015/032175, filed May 22, 2015 and titled LIGHT EMISSION REDUCING FILM FOR ELECTRONIC DEVICES, International Application under the Patent Cooperation Treaty No. PCT/US2016/037457, filed Jun. 14, 2016 and titled LIGHT EMISSION REDUCING COMPOUNDS FOR ELECTRONIC DEVICES, and any other U.S., International, or national phase patent applications stemming from the aforementioned applications.

The aforementioned patent applications are hereby incorporated by reference, such incorporation being limited such that no subject matter is incorporated that is contrary to the explicit disclosure herein. Any incorporation by reference of documents above is further limited such that no claims included in the documents are incorporated by reference herein. Any incorporation by reference of documents above is yet further limited such that any definitions provided in the documents are not incorporated by reference herein unless expressly included herein.

FIELD OF THE TECHNOLOGY

The present disclosure relates to absorbing compound or compounds that can be placed on or incorporated into an electronic device, including the display screen of an electronic device.

BACKGROUND

Electronic digital devices typically emit a spectrum of light, consisting of rays of varying wavelengths, of which the human eye is able to detect a visible spectrum between about 350 to about 700 nanometers (nm). It has been appreciated that certain characteristics of this light, both in the visible and nonvisible ranges, may be harmful to the user, and lead to health symptoms and adverse health reactions, such as, but not limited to, eyestrain, dry and irritated eyes, fatigue, blurry vision and headaches. There may be a link between exposure to the blue light found in electronic devices and human health hazards, particularly with potentially harmful risks for the eye. Some believe that exposure to the blue light and/or high energy visible light, such as that emitted by screens of digital devices could lead to age-related macular degeneration, decreased melatonin levels, acute retinal injury, accelerated aging of the retina, and disruption of cardiac rhythms, among other issues. Additional research may reveal additional musculoskeletal issues that result from prolonged exposure to the blue light spectrum.

More specifically, high energy visible (HEV) light emitted by digital devices is known to increase eye strain more than other wavelengths in the visible light spectrum. Blue light can reach deeper into the eye than, for example, ultraviolet light and may cause damage to the retina. Additionally, there may also be a causal link between blue light exposure and the development of Age-related Macular Degeneration (AMD) and cataracts. Additionally, the use of digital electronic devices is known to cause eye strain symptoms. The damage is thought to be caused by HEV light that penetrates the macular pigment, causing more rapid retinal changes.

Additionally, blue light exposure suppresses melatonin for about twice as long as green light and shifts circadian rhythms by twice as much. Blue wavelengths of light seem to be the most disruptive at night. Studies have also shown that blue light frequencies, similar to those generated by LEDs from electronic devices, such as smart phones, are 50 to 80 times more efficient in causing photoreceptor death than green light. Exposure to the blue light spectrum seem to accelerate AMD more than other areas of the visible light spectrum. However, it is also suspected that exposure to the red and green light spectrums may also present health risks, which can be mitigated by absorption of light produced by devices in that wavelength range.

Further, ultraviolet A (UVA) light (in the 320-380 nm range) is of particular concern to eye care professionals. UVA light is considered to be damaging because it directly affects the crystalline lens of the human eye. In one embodiment, the film 200 reduces the High Energy Visible light in accordance with the standards set by the International Safety Equipment Association, specifically the ANSI/ISEA Z87.1-2010 standard, which weighs the spectral sensitivity of the eye against the spectral emittance from the 380-1400 nm range.

Although the light generated by LEDs from digital devices appears normal to human vision, a strong peak of blue light ranging from 380-500 nanometers is also emitted within the white light spectrum produced by the screens of such digital devices. As this blue light corresponds to a known spectrum for retinal hazards, a means for protecting users from exposure to such light is needed.

Optical filters are used in a wide range of applications including light filters for LCD (Liquid Crystal Display) retardation films. LCD retardation films use alternate layers of materials comprised of an electroplated pigment, pigment impregnated or a printing method materials. These methods are compromised when they experience friction, heat or moisture and may cause a ghosting effect. Optical density transmissivity and sustainability requirements may also fail due to moisture and mechanical integrity.

While some measures have been taken to reduce exposure to these harmful rays, these measure have been inadequate. Some measures have implemented software solutions to decrease the wavelengths emitted, but they are easily altered to be less effective and can change the viewing experience by blocking too much light from a chosen wavelength and, therefore, changing the colors viewable to a user. Other measures have implemented physical devices that are placed over screens. However, these devices severely alter the colors viewable to a user and, in most cases, completely block at least one entire color from the color spectrum.

More specifically, current film substrate technologies often lack desired optical properties such as stability to UV light, selective transmissivity in the visible range, and absorption in the UV and high intensity blue light range, or other absorption characteristics. Current film substrates also lack the desired mechanical properties such as heat resistance and mechanical robustness at the desired thinness. Glass, polycarbonate, acrylic, and nylon lenses and films exist, but may be unable to sustain dye or pigment dispersion and achieve an optical density sufficient to maintain the high transmission values at this thickness. In one embodiment, an F700 film, such as that produced by Kentek Corporation, is resistant to moisture and humidity. Such a film is preferable to glass, which may require re-polishing. Increased color resolution, repeatability and the lack of a binder agent requirement are other benefits.

SUMMARY

In this disclosure, we describe concepts for double-notch filters for electronic devices that filter light from both the blue spectrum as well as the red spectrum in narrow wavelength bands, or “notches.” A single notch blue filtering/absorbing filter, by removing blue light, can cause the resulting filtered light to shift to a lower color temperature (compared to the spectrum of light input to the filter). This can be undesirable for at least color management reasons. By also removing a narrow-band portion of light in a red part of the spectrum, the color temperature can be shifted back to a higher value, which may be more desirable for color management.

In some examples, a double-notch filter can, using input light from a conventional LED-backlit LCD display, output light that can be measured as substantially satisfying criteria for a D65 white point. In some examples, a double-notch filter can output light that can be measured as nearly satisfying criteria for a D65 white point, to within +/− 500 Kelvin. In some examples, a double-notch filter can output light that can be measured as nearly satisfying criteria for a D65 white point, to within +/− 1000 Kelvin.

The above summary is not intended to describe each and every example or every implementation of the disclosure. The Description that follows more particularly exemplifies various illustrative embodiments.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A illustrates a light absorbent film according to one embodiment of the present disclosure.

FIG. 1B illustrates a light absorbent film according to one embodiment of the present disclosure.

FIG. 1C illustrates a light absorbent film according to one embodiment of the present disclosure.

FIG. 1D illustrates a transmission curve for a light absorbent film according to one embodiment of the present disclosure.

FIG. 1E illustrates a transmission curve for a light absorbent film according to one embodiment of the present disclosure.

FIG. 2A illustrates an exemplary interaction between an eye and a device with a light absorbent film according to one embodiment of the present disclosure.

FIG. 2B illustrates exemplary effectiveness wavelength absorbance ranges for light absorbent films.

FIG. 2C-1 illustrates a plurality of absorbing compounds that may be utilized to achieve the desired characteristics of one embodiment of a light absorbent film.

FIG. 2C-2 illustrates a plurality of absorbing compounds that may be utilized to achieve the desired characteristics of one embodiment of a light absorbent film.

FIG. 2C-3 illustrates a plurality of absorbing compounds that may be utilized to achieve the desired characteristics of one embodiment of a light absorbent film.

FIG. 2C-4 illustrates a plurality of absorbing compounds that may be utilized to achieve the desired characteristics of one embodiment of a light absorbent film.

FIG. 2C-5 illustrates a plurality of absorbing compounds that may be utilized to achieve the desired characteristics of one embodiment of a light absorbent film.

FIG. 2C-6 illustrates a plurality of absorbing compounds that may be utilized to achieve the desired characteristics of one embodiment of a light absorbent film.

FIG. 2C-7 illustrates a plurality of absorbing compounds that may be utilized to achieve the desired characteristics of one embodiment of a light absorbent film.

FIG. 3A depicts a graph illustrating transmission as a function of wavelength for a variety of absorbent films according to one embodiment of the present disclosure.

FIG. 4A depicts a method for generating a light-absorbing film for a device according to one embodiment of the present disclosure.

FIG. 4B depicts a method for generating a light-absorbing film for a device according to one embodiment of the present disclosure.

FIG. 4C depicts a method for generating a light-absorbing film for a device according to one embodiment of the present disclosure.

FIG. 5A depicts an exploded view of the screen of an electronic device comprised of several layers of glass and/or plastic.

FIG. 5B depicts the screen of an electronic device comprised of several layers of glass and/or plastic.

FIG. 5C depicts an exploded view of the screen of an electronic device comprised of several layers of glass and/or plastic with an absorbing film layer inserted between two of the several layers.

FIG. 5D depicts the screen of an electronic device comprised of several layers of glass and/or plastic with an absorbing film layer inserted between two of the several layers.

FIG. 5E depicts an exploded view of the screen of an electronic device comprised of several layers of glass and/or plastic wherein a light-absorbing adhesive is added to one of the several layers.

FIG. 5F depicts the screen of an electronic device comprised of several layers of glass and/or plastic wherein a light-absorbing coating is added to one of the several layers.

FIG. 5G depicts light waves emitted from the screen of an electronic device comprised of several layers of glass and/or plastic.

FIG. 5H depicts light waves emitted from, and blocked by, the screen of an electronic device comprised of several layers of glass and/or plastic with an absorbing film layer inserted between two of the several layers.

FIG. 6A depicts a virtual reality headset with one embodiment of a light-absorbing layer inserted within the virtual reality headset.

FIG. 6B depicts a virtual reality headset with one embodiment of a light-absorbing layer inserted within the virtual reality headset.

FIG. 6C depicts a virtual reality headset with one embodiment of a light-absorbing layer inserted within the virtual reality headset.

FIG. 7 is a schematic cross-sectional view of an example display system with which systems of the present disclosure may be beneficially employed.

FIG. 8 shows spectra for changing concentrations of a narrow notch blue light filtering dye of the present disclosure.

FIG. 9 illustrates the effects of varying concentrations of color correction dye.

FIG. 10 illustrates the effects of varying concentrations of a broad band blue absorption dye, without a color correction dye.

FIG. 11 illustrates color correction optimization trials for an LED backlight.

DETAILED DESCRIPTION

Generally, the present disclosure relates to an absorbing compound or compounds that can be combined with one or more polymer substrates to be placed on or incorporated into an electronic device. The absorbing compound is, ideally, blue-based and provides protection to an individual from the potentially harmful light emitted by the electronic device, and the polymer substrates are used for application to or in the electronic device. The absorbing compound and polymer substrate combinations described herein can include material for making optical filters with defined transmission and optical density characteristics for visible wavelength transmissivity. The material to make such filters, in some embodiments, can include an organic dye impregnated polycarbonate composition. In application, the protective film can be applied to a device's screen surface after purchase of the electronic device or the protective film can be incorporated into the screen during production. In a further embodiment, the absorbing compound can be applied as a protective coating layer to an existing film layer or other substrate in a device screen.

Film and Film Properties

FIGS. 1A-1C illustrate an exemplary film that is useful in one embodiment of the present disclosure to absorb specific wavelengths of light. A plurality of film materials may be appropriate, as described in any of the embodiments included below. A film material may be chosen for a specific application based on a variety of properties. For example, a film material may be chosen for a specific hardness, scratch resistance, transparency, conductivity, etc. In one embodiment, the film is comprised of at least one absorbing compound and from a polymer material, such as any one or more of the polymer bases listed below in Table 1. As mentioned above, the polymer bases are chosen based on the type of technology the absorbing compounds are being applied to.

TABLE 1 POLYMER BASES FOR ABSORBANCE FILM Polymer base Characteristics Acrylic impact modified, chemical resistance, superb weatherability, UV resistance and transparency Epoxy Resistivity to energy and heat Polyamide Thermoformabilty, abrasion resistance, good mechanical properties; High tensile strength and elastic modulus, impact and crack resistance Polycarbonate Impact strength even at low temperatures. dimensional stability, weather resistance, UV resistance, flame retardant, super-weather resistance and heat stability, optical properties Polyester Optics, mechanical Strength, Solvent Resistant, Tear and puncture resistant Co-polyester (PETG, printable, scratch hardness PCTG) Polyethylene Geomembrane windows, global recylability, good moisture barrier, clarity, strength, toughness Polyolefin Good chemical resistance Polypropylene High impact and puncture resistance, excellent extensibility Polystyrene good printablity, high impact resistance, good dimensional stability, easy to thermoform Polysolfone high strength, amorphous thermoplastic, clarity and toughness, high- heat deflection temperature, excellent thermal stability, excellent hydrolitic stability Polyurethane Excellent laminated transparency, microbial resistance, UV stability, contains adhesion promoter, medium Durometer, Medium Modulus, Excellent Cold impact Polyvinyl Chloride Weathering resistance, abrasion resistance, chemical resistance, flow characteristics, stable electrical properties Styrene Acrylonitrile superior mechanical strength, chemical resistance, heat resistance, durability, simplicity of production, recyclability, impact strength, heat resistance, good impact resistance, excellent hygiene, sanitation and safety benefits.

In one embodiment, any one or more of the polymers listed in Table 1 is combined with one or more absorbing compounds, for example those listed below in Table 2, to generate a film 100 that can be utilized with one or more devices, for example smartphones, laptops, tablets, glasses, or any other transparent surface utilized with an electronic display device. In one embodiment, the polymer base for the film 100 is chosen, at least in part, based on transparency, such that a user can still view a screen of an electronic display device through the film 100. In another embodiment, the polymer base is chosen, at least in part, based on its compatibility with a desired absorbing compound. In further embodiments, the polymer base is chosen based on the substrate to which the absorbing compound is incorporate in or attached to.

In accordance with one embodiment, as shown in FIG. 1A, a film 100 is applied to a device 102 with a screen 104. While FIG. 1A shows the device 102 as a smartphone, the film 100 can illustratively be designed to be applied to any other device, such as, for example the laptop 152 with film 150 over screen 154 shown in FIG. 1B. Additionally, in another embodiment, the film 100 could be incorporated into a layer of a device, such as a contact lens or lenses of a pair of glasses.

Film 100 is formed of a suitable material, such as a polymer, and one or more light absorption dyes that selectively reduce the peaks and slopes of electromagnetic emission from occupational and personal electronic devices. Other examples of electronic devices with which such a film may be used may include for example, LEDs, LCDs, computer monitors, equipment screens, televisions, tablets, cellular phones, etc. However, it could also be used on the user-end of a viewing experience, for example incorporated into contact lenses or glasses.

FIG. 1C illustrates two layers of a film 100. In one embodiment, the film includes no antiglare coating as shown by film 170. In another embodiment, the film 100 includes a coating 172, wherein the coating 172 comprises an antiglare coating 172, a hard coating 172, and/or a tack coating 172. In one embodiment, the absorbing compound may be incorporated into the coating material directly, instead of the base film layer. This may be done, for example, due to compatibility between the absorbing compound and the desired polymer substrate.

The film 100, in one embodiment, is blue-based and has a slight color tint, as a result at least in part of the absorbing compound selected, and works as a filter to reduce light emission from the screen 104. In one embodiment, under a CIE light source D65, a film 100 having a 7.75 mil thickness is a light blue-green color with (L, a, b) values of (90.24, −12.64, 3.54) with X-Y-Z values of (67.14, 76.83,78.90) respectively. In another embodiment, the film 100 appears lighter due to reduced loading.

In one embodiment, film 100 is configured to reduce light emission across a broad spectrum of light, for example, the 200 nm to the 3000 nm range. In another example, film 100 can be configured to reduce light emission in only a portion of this broad spectrum, for example, only within the visible spectrum 390 nm to 700 nm, or only within a portion of the visible spectrum, such as within the spectrum 200 nm to 1400 nm.

In one embodiment, film 100 is configured to normalize the light emission from screen 104 such that peaks of light intensity across the spectrum are reduced. In one example, the light emission intensity is normalized to a maximum absorbance level between 0.0035 and 0.0038.

In the illustrated embodiment of FIG. 1A, film 100 is configured for use with devices having touch screens (e.g. a capacitive touch screen). When used with a capacitive touch screen, such as screen 104, film 100 may be configured to have suitable electrical properties such that the user touch inputs are accurately registered by the device. For example, film 100 may have a dielectric constant that is less than 4. In another example, the dielectric constant is less than 3. In one particular embodiment, the dielectric constant of film 100 is between 2.2 and 2.5.

In one embodiment, film 100 has a thickness between 10-30 mil and a hardness above 30 Rockwell R. In one embodiment, the hardness of film 100 is between 45-125 Rockwell R.

While embodiments shown in FIGS. 1A-1C are described in the context of a film applied to an electronic device after manufacture, it is noted that the described features can be used in other applications, such as, but not limited to, application to eye wear (e.g. glasses, contacts, etc.) as well as applications on windows, for example, to protect against lasers. It may also be used on any other surface through which light is transmitted and may be received by a human eye. In one embodiment, film 100 is applied to eyewear lenses, such as corrective lens glasses, sunglasses, safety glasses, etc. While the film 100 is shown in FIGS. 1A and 1B as being applied as an aftermarket feature to a device 102, and provided to a user as shown in FIG. 1C, in another embodiment, the film 100 is included within a device 102 during a manufacture of the device 102 such that the film 100 is located behind a screen 104 or comprises the screen 104 of the device 102.

FIGS. 1D-1E illustrate a plurality of transmission curves for different films that may be useful in embodiments of the present disclosure. The transmission characteristics of a film, for example film 100, may be defined by a transmission curve, such as those shown in FIG. 1D or 1E. Specifically, curve 180 illustrates an exemplary transmission curve of filter glass. Curve 182 illustrates an exemplary transmission curve of a film 100 with a thickness of 4 mil. Curve 184 illustrates an exemplary transmission curve for a film 100 with a thickness of 7.75 mil. The transmission curve includes a transmission local maximum in a visible light wavelength range and a first and second transmission local minimums proximate each end of the visible light wavelength range.

In one embodiment, the transmission local maximum is at a location between 575 nm and 425 nm, the first transmission local minimum being at or around a location of about 700 nm or greater, and the second transmission local minimum being at or around a location of about 300 nm or less. The transmission local maximum may have a transmission of 85% or greater. The transmission local maximum may further have a transmission of 90% or greater. The first and second transmission local minimums may have a transmission of less than 30%, in one embodiment. In another embodiment, the first and second transmission local minimums may have a transmission of less than 5%. The transmission curve, in one embodiment, may also include a first and second 50% transmission cutoff between the respective transmission local minimums and the transmission local maximum.

The transmission curve may also include, in one embodiment, a curve shoulder formed by a reduced slope for at least of the transmission curve between 750 nm and 575 nm, which increases transmission for wavelengths at this end of the visible spectrum (e.g. red light). In one embodiment, the curve shoulder passes through a location at 644 nm ±10 nm. In other embodiments, the curve shoulder may pass through a location at 580 nm ±10 nm. One of the 50% transmission cutoffs may coincide with the curve shoulder, for example, at 644 nm ±10 nm.

As used herein, the terms “optical density” and “absorbance” may be used interchangeably to refer to a logarithmic ratio of the amount of electromagnetic radiation incident on a material to the amount of electromagnetic radiation transmitted through the material. As used herein, “transmission” or “transmissivity” or “transmittance” may be used interchangeably to refer to the fraction or percentage of incident electromagnetic radiation at a specified wavelength that passes through a material. As used herein, “transmission curve” refers to the percent transmission of light through an optical filter as a function of wavelength. “Transmission local maximum” refers to a location on the curve (i.e. at least one point) at which the transmission of light through the optical filter is at a maximum value relative to adjacent locations on the curve. “Transmission local minimum” refers to a location on the curve at which transmission is at a minimum value relative to adjacent locations on the curve. As used herein, “50% transmission cutoff” refers to a location on the transmission curve where the transmission of electromagnetic radiation (e.g. light) through the optical filter is about 50%.

In one embodiment, the transmission characteristics of the optical filters, for example those shown in FIG. 3 below, may be achieved, in one embodiment, by using a polycarbonate film as a polymer substrate, with a blue or blue-green organic dye dispersed therein. The organic dye impregnated polycarbonate film may have a thickness less than 0.3 mm. In another embodiment, the polycarbonate film may have a thickness less than 0.1 mm. The thinness of the polycarbonate film may facilitate the maximum transmission of greater than 90% of light produced by a device. In at least one embodiment, the organic dye impregnated film may have a thickness between 2.5 mils-14mils. The combination of the polycarbonate substrate and the blue or blue-green organic dye is used in one or more embodiments of the present disclosure to provide improved heat resistant and mechanical robustness even with the reduced thickness.

The polycarbonate film may include any type of optical grade polycarbonate such as, for example, LEXAN 123 R. Although polycarbonate provides desirable mechanical and optical properties for a thin film, other polymers may also be used such as a cyclic olefilm copolymer (COC).

In one embodiment, similar transmission characteristics may also be achieved, for example, by using an acrylic film with a blue-green organic dye dispersed therein. The organic dye impregnated acrylic film may have a thickness less than 0.3 mm. In another embodiment, the acrylic film may have a thickness less than 0.1 mm. The thinness of the acrylic film may facilitate the maximum transmission of greater than 90% of light produced by a device. In at least one embodiment, the organic dye impregnated film may have a thickness between 2.5 mils-14 mils. The combination of the acrylic substrate and the blue green organic dye may be used, in one or more embodiments, to provide improved heat resistant and mechanical robustness even with the reduced thickness.

In another embodiment, similar transmission characteristics may also be achieved, for example, by using an epoxy film with a blue-green organic dye dispersed therein. The organic dye impregnated epoxy film may have a thickness less than 0.1 mm. In another embodiment, the epoxy film may have a thickness less than 1 mil. The thinness of the epoxy film may facilitate the maximum transmission of greater than 90% of light produced by a device. The combination of the epoxy substrate and the blue green organic dye may be used, in one or more embodiments, to provide improved heat resistant and mechanical robustness even with the reduced thickness.

In a further embodiment, similar transmission characteristics may also be achieved, for example, by using a PVC film with a blue-green organic dye dispersed therein. The organic dye impregnated PVC film may have a thickness less than 0.1 mm. In another embodiment, the PVC film may have a thickness less than 1 mil. The thinness of the PVC film may facilitate the maximum transmission of greater than 90% of light produced by a device. The combination of the PVC substrate and the blue green organic dye may be used, in one or more embodiments, to provide improved heat resistant and mechanical robustness even with the reduced thickness.

The organic dye impregnated polycarbonate film may, in one embodiment, also have the desired optical characteristics at this reduced thickness with a parallelism of up to 25 arcseconds and a 0-30° chief ray of incident angle. In a preferred embodiment, the angle of incidence is within the range of 0-26°. The organic dye impregnated polycarbonate film may further provide improved UV absorbance with an optical density of greater than 5 in the UV range. The exemplary combination of a polycarbonate substrate with a blue-green dye is provided for example purposes only. It is to be understood that any of the absorbing compounds described in detail below could be combined with any of the polymer substrates described above to generate a film with the desired mechanical properties and transmissivity.

Embodiments of the optical filter 100, as described herein, may be used for different applications including, without limitation, as a light filter to improve color rendering and digital imaging, an LCD retardation film with superior mechanical properties, an excellent UV absorbance, a light emission reducing film for an electronic device to reduce potentially harmful wavelengths of light, and an optically correct thin laser window with high laser protection values. In these embodiments, the optical filter may be produced as a thin film with the desired optical characteristics for each of the applications.

In some embodiments, the color rendering index (CRI) change resulting from transmission through embodiments of the present disclosure is minimal. For example, the difference in the CRI value before and after application of embodiments of the present disclosure to an electronic device may be between one and three. Therefore, when embodiments of the present disclosure are applied to the display of an electronic device, a user viewing the display will see minimal, if any, change in color and all colors will remain visible.

Absorbance and Absorbing Materials

Absorbance of wavelengths of light occurs as light encounters a compound. Rays of light from a light source are associated with varying wavelengths, where each wavelengths is associated with a different energies. When the light strikes the compound, energy from the light may promote an electron within that compound to an anti-bonding orbital. This excitation occurs, primarily, when the energy associated with a particular wavelength of light is sufficient to excite the electron and, thus, absorb the energy. Therefore, different compounds, with electrons in different configurations, absorb different wavelengths of light. In general, the larger the amount of energy required to excite an electron, the lower the wavelength of light required. Further, a single compound may absorb multiple wavelength ranges of light from a light source as a single compound may have electrons present in a variety of configurations.

FIG. 2A illustrates an exemplary interaction between a device and an eye with an exemplary film that may be useful in one embodiment of the present disclosure. In one embodiment, the film 200 comprises a film placed on the device 202, for example as an after-market addition. In another embodiment, the film 200 comprises a portion of the device 202, for example the screen of device 202. In a further embodiment, the film is a physical barrier worn on or near the eye 250, for example as a contact lens, or as part of the lenses of a pair of glasses; either as an after-market application or part of the lenses themselves.

As shown in FIG. 2A, device 202 produces a plurality of wavelengths of light including, high intensity UV light 210, blue violet light 212, blue turquoise light 214 and visible light 218. High intensity UV light may comprise, in one embodiment, wavelengths of light in the 315-380 nm range. Light in this wavelength range is known to possibly cause damage to the lens of an eye. In one embodiment, blue-violet light 212 may comprise wavelengths of light in the 380-430 nm range, and is known to potentially cause age-related macular degeneration. Blue-turquoise light 214 may comprise light in the 430-500 nm range and is known to affect the sleep cycle and memory. Visible light 218 may also comprise other wavelengths of light in the visible light spectrum.

As used herein, “visible light” or “visible wavelengths” refers to a wavelength range between 380 to 750 nm. “Red light” or “red wavelengths” refers to a wavelength range between about 620 to 675 nm. “Orange light” or “orange wavelengths” refers to a wavelength range between about 590 to 620 nm. “Yellow light” or “yellow wavelengths” refers to a wavelength range between about 570 to 590 nm. “Green light” or “green wavelengths” refers to a wavelength range between about 495 to 570 nm. “Blue light” or “blue wavelengths” refers to a wavelength range between about 450 to 495 nm. “Violet light” or “violet wavelengths” refers to a wavelength range between about 380 to 450 nm. As used herein, “ultraviolet” or “UV” refers to a wavelength range that includes wavelengths below 350 nm, and as low as 10 nm. “Infrared” or “IR” refers to a wavelength range that includes wavelengths above 750 nm, and as high as 3,000 nm.

When a particular wavelength of light is absorbed by a compound, the color corresponding to that particular wavelength does not reach the human eye and, thus, is not seen. Therefore, for example, in order to filter out UV light from a light source, a compound may be introduced into a film that absorbs light with a wavelength below 350 nm. A list of some exemplary light-absorbing compounds for various ranges of wavelengths are presented in Table 2 below, and correspond to exemplary absorption spectra illustrated in FIG. 2D. The absorbing materials used in the present disclosure achieve protection for the individual while simultaneously leaving the color imagery of the device intact. Therefore, the absorbing compounds ideally block only a portion of the wavelength ranges for each color, so that each hue is still visible to the individual viewing the screen of the electronic device. Further, the wavelength ranges that are blocked may be wavelength ranges for a color that are not visible to a person. Therefore, in some embodiments, the present disclosure provides a neutral density filter allowing for full color recognition.

TABLE 2 ABSORBING MATERIALS AND WAVELENGTH RANGES Exemplary Polymer 260-400 nm 400-700 nm Infrared Substrate Target Range Target Range Target Range Polycarbonate 1002 1004 1006 PVC 1008 1010 1020 Epoxy 1022 1018 1026 Polyester 1028 1024 1032 Polyethylene 1040 1030 1038 Polyamide 1046 1036 1044 1042 1050 1048

In one embodiment, a film 200 is manufactured by choosing one of the substrates from the first column of Table 2, and selecting one absorbing column from one or more of columns 2-4, depending on the wavelength range to be targeted for absorption. In an embodiment, a UV-targeting absorbing compound is not needed when the polymer substrate contains a UV inhibitor, a UV stabilizer, or otherwise inherently possesses UV absorbing properties. Absorbing compounds then can be selected from any of the columns 2-4 for addition in order to increase absorption of light produced in the target wavelength ranges. Absorbing compounds can be selected in combination, provided that high transmission of light is maintained, and the color tint is maintained, such that color integrity produced by a device remains true. In one embodiment, the absorbing compounds are provided in a polymer or pellet form and coextruded with the polymer substrate to produce the film 200. In another embodiment, the absorbing compound is provided in a separate layer from the polymer substrate, for example as a component in a coating layer applied to the polymer substrate, or an additional scratch resistance layer.

Additionally, many of the exemplary compounds described in each of columns 2, 3 and 4 can be substituted to produce the desired characteristics in other polymer substrates. For example, while compound 1002 is listed as an ideal compound for combination with a polycarbonate substrate, compound 1002 is also known as a compatible compound for impregnation with PVC, acetals and cellulose esters. Some potential exemplary combinations of the compounds and polymer substrates presented in Table 2 are described in further detail in the examples below. However, it is to be understood that other possible combinations, including with polymer substrates listed in Table 1 and not presented again in Table 2, are possible.

In one embodiment, the organic dye dispersed in the polymer substrate provides selective transmission characteristics including, for example, reducing transmissivity for blue light wavelengths and/or red light wavelengths. The reduction of these unnaturally high emissivity levels of a particular band or wavelength to a level more representative of daylight helps to decrease some of the undesirable effects of the use of digital electronic devices. In addition, the optical film may reduce the HEV light in the range that is emitted by a device 202. However, the optical film 200 is, in one embodiment, also configured in order to allow other blue wavelengths of light, for example the color cyan, through in order to preserve color rendition by the device 202.

Polycarbonate Example

In one embodiment, the film 200 comprises a polycarbonate substrate impregnated with an absorbing compound 1002 selected to target light produced in the 260-400 nm range. In one embodiment, absorbing compound 1002, is selected for a peak absorption in the 300-400 nm range. One exemplary absorbing compound is, for example, Tinuvin®, provided by Ciba Specialty Chemicals, also known as 2-(2H-benzotriazol-2-yl)-p-cresol. However, any other exemplary absorbing compound with strong absorption characteristics in the 300-400 nm range would also be suitable for absorbing UV light. In an embodiment where Tinuvin® is utilized to provide UV protection, other polymer substrates, such as those listed in Table 1, would also be suitable for the generation of film 200.

In one embodiment, the film 200 comprises a polycarbonate substrate impregnated with an absorbing compound 1004 selected to target light produced in the 400-700 nm range. In one embodiment, absorbing compound 1004 is selected for a peak absorption in the 400-700 nm range. Specifically, in one embodiment, absorbing compound 1004 is selected for peak absorption in the 600-700 nm range. Even more specifically, in one embodiment, absorbing compound is selected for peak absorption in the 635-700 nm range. One exemplary absorbing compound is a proprietary compound produced by Exciton®, with commercial name ABS 668. However, any other exemplary absorbing compound with strong absorption in the 600-700 nm range of the visible spectrum may also be suitable for the generation of film 200. In another embodiment, compound 1004 may also be combined with a different polymer substrate from Table 1.

In one embodiment, the film 200 comprises a polycarbonate substrate impregnated with an absorbing compound 1006 selected to target light produced in the infrared range. In one embodiment, absorbing compound 1006 is selected to target light produced in the 800-1100 nm range. Specifically, in one embodiment, absorbing compound 1006 is selected for a peak absorption in the 900-1000 nm range. One exemplary compound may be the NIR1002A dye produced by QCR Solutions Corporation. However, any other exemplary absorbing compound with strong absorption in the infrared range may also be suitable for the generation of film 200. In another embodiment, compound 1006 may also be combined with a different polymer substrate from Table 1.

In one embodiment, a polymer substrate is impregnated with a combination of compounds 1002, 1004, and 1006 such that any two of compounds 1002, 1004, and 1006 are both included to form film 200. In another embodiment, all three of compounds 1002, 1004, and 1006 are combined within a polymer substrate to form film 200.

In another embodiment, the polycarbonate substrate is provided in a film 200 along with any one of compounds 1002, 1008, 1022, 1028, 1040 or 1046. This may be, in one embodiment, in combination with any one of compounds 1004, 1010, 1018, 1024, 1030, 1036, 1042 or 1048. This may be, in one embodiment, in combination with any one of compounds 1006, 1020, 1026, 1032, 1038, 1044 or 1050.

PVC Filter Example

In one embodiment, the film 200 comprises a poly-vinyl chloride (PVC) substrate impregnated with an absorbing compound 1008 selected to target light produced in the 260-400 nm range. In one embodiment, absorbing compound 1008, is selected for a peak absorption in the 320-380 nm range. One exemplary absorbing compound is DYE VIS 347, produced by Adam Gates & Company, LLC. However, any other exemplary absorbing compound with strong absorption characteristics in the 300-400 nm range would also be suitable for absorbing UV light. In an embodiment where DYE VIS 347 is utilized to provide UV protection, other polymer substrates, such as those listed in Table 1, would also be suitable for the generation of film 200.

In one embodiment, the film 200 comprises a PVC substrate impregnated with an absorbing compound 1010 selected to target light produced in the 400-700 nm range. Specifically, in one embodiment, absorbing compound 1010 is selected for peak absorption in the 550-700 nm range. Even more specifically, in one embodiment, absorbing compound is selected for peak absorption in the 600-675 nm range. One exemplary absorbing compound is ADS640PP, produced by American Dye Source, Inc., also known as 2-[5-(1,3-Dihydro-3,3-dimethyl-1-propyl-2H-indol-2-ylidene)-1,3-pentadienyl]-3,3-dimethyl-1-propyl-3H-indolium perchlorate. However, any other exemplary absorbing compound with strong absorption in the 600-700 nm range of the visible spectrum may also be suitable for the generation of film 200. In another embodiment, compound 1010 may also be combined with a different polymer substrate from Table 1.

In one embodiment, a polymer substrate is impregnated with a combination of compounds 1008 and 1010. In another embodiment, the PVC substrate is provided in a film 200 along with any one of compounds 1002, 1008, 1022, 1028, 1040 or 1046. This may be, in one embodiment, in combination with any one of compounds 1004, 1010, 1018, 1024, 1030, 1036, 1042 or 1048. This may be, in one embodiment, in combination with any one of compounds 1006, 1020, 1026, 1032, 1038, 1044 or 1050.

Epoxy Example

In one embodiment, the film 200 comprises an epoxy substrate impregnated with an absorbing compound 1016 selected to target light produced in the 260-400 nm range. In one embodiment, absorbing compound 1016, is selected for a peak absorption in the 300-400 nm range. Specifically, in one embodiment, absorbing compound 1016 is selected for peak absorption in the 375-410 range. One exemplary absorbing compound is, for example, ABS 400, produced by Exciton, with a peak absorbance at 399 nm. However, any other exemplary absorbing compound with strong absorption characteristics in the 300-400 nm range would also be suitable for absorbing UV light. In an embodiment where ABS 400 is utilized to provide UV protection, other polymer substrates, such as those listed in Table 1, may also be suitable for the generation of film 200.

In one embodiment, the film 200 comprises an epoxy substrate impregnated with an absorbing compound 1018 selected to target light produced in the 400-700 nm range. In one embodiment, absorbing compound 1018 is selected for a peak absorption in the 400-700 nm range. Specifically, in one embodiment, absorbing compound 1018 is selected for peak absorption in the 600-700 nm range. Even more specifically, in one embodiment, absorbing compound is selected for peak absorption in the 650-690 nm range. One exemplary absorbing compound is a proprietary compound produced by QCR Solutions Corporation, with commercial name VIS675F and peak absorption, in chloroform, at 675 nm. However, any other exemplary absorbing compound with strong absorption in the 600-700 nm range of the visible spectrum may also be suitable for the generation of film 200. In another embodiment, compound 1018 may also be combined with a different polymer substrate from Table 1.

In one embodiment, the film 200 comprises an epoxy substrate impregnated with an absorbing compound 1020 selected to target light produced in the infrared range. In one embodiment, absorbing compound 1020 is selected to target light produced in the 800-1100 nm range. Specifically, in one embodiment, absorbing compound 1020 is selected for a peak absorption in the 900-1080 nm range. In one embodiment, absorbing compound is a proprietary compound produced by QCR Solutions Corporation, with commercial name NIR1031M, and peak absorption, in acetone, at 1031 nm. However, any other exemplary absorbing compound with strong absorption in the infrared range may also be suitable for the generation of film 200. In another embodiment, compound 1020 may also be combined with a different polymer substrate from Table 1.

In one embodiment, a polymer substrate is impregnated with a combination of compounds 1016, 1018, and 1020 such that any two of compounds 1016, 1018, and 1020 are both included to form film 200. In another embodiment, all three of compounds 1016, 1018, and 1020 are combined within a polymer substrate to form film 200.

In another embodiment, the epoxy substrate is provided in a film 200 along with any one of compounds 1002, 1008, 1022, 1028, 1040 or 1046. This may be, in one embodiment, in combination with any one of compounds 1004, 1010, 1018, 1024, 1030, 1036, 1042 or 1048. This may be, in one embodiment, in combination with any one of compounds 1006, 1020, 1026, 1032, 1038, 1044 or 1050.

Polyamide Example

In one embodiment, the film 200 comprises a polyamide substrate impregnated with an absorbing compound 1022 selected to target light produced in the 260-400 nm range. In one embodiment, absorbing compound 1022, is selected for a peak absorption in the 260-350 nm range. One exemplary absorbing compound is, for example, produced by QCR Solutions Corporation with product name UV290A. However, any other exemplary absorbing compound 1022 with strong absorption characteristics in the 260-400 nm range would also be suitable for absorbing UV light. In an embodiment where UV290A is utilized to provide UV protection, other polymer substrates, such as those listed in Table 1, would also be suitable for the generation of film 200.

In one embodiment, the film 200 comprises a polyamide substrate impregnated with an absorbing compound 1024 selected to target light produced in the 400-700 nm range. In one embodiment, absorbing compound 1024 is selected for a peak absorption in the 600-700 nm range. Specifically, in one embodiment, absorbing compound 1024 is selected for peak absorption in the 620-700 nm range. One exemplary absorbing compound is a proprietary compound produced by Adam Gates & Company, LLC with product name DYE VIS 670, which also has an absorption peak between 310 and 400 nm. However, any other exemplary absorbing compound with strong absorption in the 600-700 nm range of the visible spectrum may also be suitable for the generation of film 200. In another embodiment, compound 1024 may also be combined with a different polymer substrate from Table 1.

In one embodiment, the film 200 comprises a polyamide substrate impregnated with an absorbing compound 1026 selected to target light produced in the infrared range. In one embodiment, absorbing compound 1026 is selected to target light produced in the 800-1200 nm range. Specifically, in one embodiment, absorbing compound 1026 is selected for a peak absorption in the 900-1100 nm range. One exemplary absorbing compound is a proprietary compound produced by QCR Solutions Corporation, with product name NIR1072A, which has an absorbance peak at 1072 nm in acetone. However, any other exemplary absorbing compound with strong absorption in the infrared range may also be suitable for the generation of film 200. In another embodiment, compound 1026 may also be combined with a different polymer substrate from Table 1.

In one embodiment, a polymer substrate is impregnated with a combination of compounds 1022, 1024, and 1026 such that any two of compounds 1022, 1024, and 1026 are both included to form film 200. In another embodiment, all three of compounds 1022, 1024, and 1026 are combined within a polymer substrate to form film 200.

In another embodiment, the polyamide substrate is provided in a film 200 along with any one of compounds 1002, 1008, 1022, 1028, 1040 or 1046. This may be, in one embodiment, in combination with any one of compounds 1004, 1010, 1018, 1024, 1030, 1036, 1042 or 1048. This may be, in one embodiment, in combination with any one of compounds 1006, 1020, 1026, 1032, 1038, 1044 or 1050.

Polyester Example

In one embodiment, the film 200 comprises a polyester substrate impregnated with an absorbing compound 1036 selected to target light produced in the 400-700 nm range. In one embodiment, absorbing compound 1036 is selected for a peak absorption in the 600-750 nm range. Specifically, in one embodiment, absorbing compound 1036 is selected for peak absorption in the 670-720 nm range. One exemplary absorbing compound is a proprietary compound produced by Exciton®, with commercial name ABS 691, which has an absorption peak at 696 nm in polycarbonate. However, any other exemplary absorbing compound with strong absorption in the 600-700 nm range of the visible spectrum may also be suitable for the generation of film 200. In another embodiment, compound 1036 may also be combined with a different polymer substrate from Table 1.

In one embodiment, the film 200 comprises a polyester substrate impregnated with an absorbing compound 1038 selected to target light produced in the infrared range. In one embodiment, absorbing compound 1038 is selected to target light produced in the 800-1300 nm range. Specifically, in one embodiment, absorbing compound 1038 is selected for a peak absorption in the 900-1150 nm range. One exemplary absorbing compound 1038 is a proprietary compound produced by Adam Gates & Company, LLC, with product name IR Dye 1151, which has an absorbance peak at 1073 nm in methyl-ethyl ketone (MEK). However, any other exemplary absorbing compound with strong absorption in the infrared range may also be suitable for the generation of film 200. In another embodiment, compound 1038 may also be combined with a different polymer substrate from Table 1.

In one embodiment, a polymer substrate is impregnated with a combination of compounds 1036, and 1038. In another embodiment, the polyester substrate is provided in a film 200 along with any one of compounds 1002, 1008, 1022, 1028, 1040 or 1046. This may be, in one embodiment, in combination with any one of compounds 1004, 1010, 1018, 1024, 1030, 1036, 1042 or 1048. This may be, in one embodiment, in combination with any one of compounds 1006, 1020, 1026, 1032, 1038, 1044 or 1050.

Polyethylene Example

In one embodiment, the film 200 comprises a polyethylene substrate impregnated with an absorbing compound 1042 selected to target light produced in the 400-700 nm range. In one embodiment, absorbing compound 1042 is selected for a peak absorption in the 600-750 nm range. Specifically, in one embodiment, absorbing compound 1042 is selected for peak absorption in the 670-730 nm range. One exemplary absorbing compound is a proprietary compound produced by Moleculum, with commercial name LUM690, which has an absorption peak at 701 nm in chloroform. However, any other exemplary absorbing compound with strong absorption in the 600-700 nm range of the visible spectrum may also be suitable for the generation of film 200. In another embodiment, compound 1042 may also be combined with a different polymer substrate from Table 1.

In one embodiment, the film 200 comprises a polyethylene substrate impregnated with an absorbing compound 1044 selected to target light produced in the infrared range. In one embodiment, absorbing compound 1044 is selected to target light produced in the 800-1100 nm range. Specifically, in one embodiment, absorbing compound 1044 is selected for a peak absorption in the 900-1100 nm range. One exemplary absorbing compound is a proprietary compound produced by Moleculum, with commercial name LUM1000A, which has an absorption peak at 1001 nm in chloroform. However, any other exemplary absorbing compound with strong absorption in the infrared range may also be suitable for the generation of film 200. In another embodiment, compound 1044 may also be combined with a different polymer substrate from Table 1.

In one embodiment, a polymer substrate is impregnated with a combination of compounds 1040, 1042, and 1044 such that any two of compounds 1040, 1042, and 1044 are both included to form film 200. In another embodiment, all three of compounds 1040, 1042, and 1044 are combined within a polymer substrate to form film 200.

In another embodiment, the polycarbonate substrate is provided in a film 200 along with any one of compounds 1002, 1008, 1022, 1028, 1040 or 1046. This may be, in one embodiment, in combination with any one of compounds 1004, 1010, 1018, 1024, 1030, 1036, 1042 or 1048. This may be, in one embodiment, in combination with any one of compounds 1006, 1020, 1026, 1032, 1038, 1044 or 1050.

Other Exemplary Embodiments

The blue green organic absorbing compound may be selected to provide the selective transmission and/or attenuation at the desired wavelengths (e.g. by attenuating blue light relative to red light). The blue green organic dye may include, for example, a blue green phthalocyanine dye that is suitable for plastic applications and provides good visible transmittance, light stability, and thermal stability with a melting point of greater than 170° C. The organic dye impregnated polycarbonate compound may include about 0.05% to 2% absorbing compound, by weight. The blue green phthalocyanine dye may be in the form of a powder that can be dispersed in a molten polycarbonate during an extruding process. The blue-green dye may also be dispersed within polycarbonate resin beads prior to an extruding process.

In another embodiment, one or more additional dyes may be dispersed within the film. To add infrared protection, for example, an additional IR filtering dye may be used to provide an optical density of 9 or greater in the IR range. One example of an IR filtering dye may include LUM1000A. The organic dye impregnated polycarbonate mixture may include about 0.05% to 2% absorbing compound, by weight.

In one embodiment, an optical filter for a digital electronic device is provided with defined electromagnetic radiation transmission characteristics with selective transmission at visible wavelengths. In one embodiment, the optical filter is engineered to block or reduce transmission of light in a plurality of wavelength ranges, for example in both the blue light wavelength range and the red light wavelength range. The optical filter may be used for a variety of applications including, without limitation, a light filter, a light emission reducing film for electronic devices, and an LCD retardation film. The optical filter is made of a composition including, in one embodiment, an organic dye dispersed or impregnated in a polymer substrate such as polycarbonate film. In another embodiment, any one or more polymer substrates may be selected from Table 1, above.

As shown in FIG. 2A, light of wavelengths 210, 212, 214 and 218 is generated by the device 202. These wavelengths of light then encounter the film 200, in one embodiment. When the wavelengths of light encounter the film 200, the film 200 is configured to allow only some of the wavelengths of light to pass through. For example, in one embodiment as shown in FIG. 2A, UV light is substantially prevented from passing through the film 200. Blue-violet light is also substantially prevented from passing through the film 200. Blue-turquoise light 214 is at least partially prevented from passing through the film 200, while allowing through some other ranges of blue light wavelengths 216 through. These may, in one embodiment, comprise wavelengths of light in the cyan color range. However, visible light 218, which may be safe for a user to view, is allowed to pass through the film in one embodiment. Once the wavelengths of light have encountered and passed through film 200, in one embodiment, they are then perceived by a human eye of a user using the device 202. In one embodiment, as shown in FIG. 2A, a region of the eye 252 is known to be highly affected by UV light, and a region of the eye 254 is known to be highly affected by blue light. By interposing a film 200 between the device 202 and the eye 250, the light rays likely to cause damage to the eye in regions 252 and 254 are thus substantially prevented from reaching the eye of a user.

FIG. 2B illustrates exemplary effectiveness wavelength absorbance ranges of a plurality of films that may be useful in one embodiment of the present disclosure. Film 200 may comprise, in one embodiment, a one or more absorption compounds configured to absorb light in one or more wavelength ranges. A range of wavelengths may be blocked by a film 272, in one embodiment, where at least some rays of light in the ranges of 300-400 nm are blocked from reaching the eye of a user by film 272, but the remainder of the wavelength spectrum is substantially unaffected. In another embodiment, a film 274 substantially reduces light in the 300-500 nm range from reaching the eye of a user, but the remainder of the wavelength spectrum is substantially unaffected. In another embodiment, a film 276 substantially reduces light in the 300-650 nm range from reaching the eye of a user, but the remainder of the wavelength spectrum is substantially unaffected. In a further embodiment, film 278 reduces the amount of light in the 300-3,000 nm range from reaching the eye of a user, but the remainder of the wavelength spectrum is substantially unaffected. Depending on different conditions affecting a user of a device 202, different films 272, 274, 276, and 278 may be applied to the user's devices 202 in order to treat or prevent a medical condition.

FIG. 2C, and the examples above, illustrate a plurality of absorbing compound spectra that may be utilized, either alone or in combination, to achieve the desired characteristics of a film, in one embodiment of the present disclosure. In one embodiment, one or more of the absorbing agents illustrated in FIG. 2C are impregnated within a polymer substrate to achieve the desired transmissivity.

In one embodiment, film 272 is configured to substantially block 99.9% of UV light, 15-20% of HEV light, and 15-20% of photosensitivy (PS) light. In one embodiment, film 272 comprises a UV-inhibiting polycarbonate substrate with a thickness of at least 5 mils. In one embodiment, the thickness is less than 10 mils. In one embodiment, film 272 also comprises a UV-inhibiting additive, comprising at least 1% of the film 272. In one embodiment, the UV-inhibiting additive comprises at least 2% of the film, but less than 3% of the film 272. In one embodiment, film 272 also comprises a hard coat. In one embodiment, film 272 can also be characterized as having an optical density that is at least 3 in the 280-380 nm range, at least 0.7 in the 380-390 nm range, at least 0.15 in the 390-400 nm range, at least 0.09 in the 400-600 nm range, and at least 0.04 in the 600-700 nm range.

In one embodiment, film 274 substantially blocks 99.9% of UV light, 30-40% of HEV light, and 20-30% of PS light. In one embodiment, film 274 comprises a UV-inhibiting polycarbonate substrate with a thickness of at least 5 mils. In one embodiment, the thickness is less than 10 mils. In one embodiment, film 274 also comprises a UV-inhibiting additive, comprising at least 1% of the film 274. In one embodiment, the UV-inhibiting additive comprises at least 2% of the film, but less than 3% of the film 274. In one embodiment, the film 274 also comprises phthalocyanine dye, comprising at least 0.0036% of the film 274. In one embodiment, the phthalocyanine dye comprises at least 0.005%, or at least 0.008%, but less than 0.01% of the film 274. In one embodiment, the film 274 comprises a hard coating. In one embodiment, film 274 can also be characterized as having an optical density that is at least 4 in the 280-380 nm range, at least 2 in the 380-390 nm range, at least 0.8 in the 290-400 nm range, at least 0.13 in the 400-600 nm range, and at least 0.15 in the 600-700 nm range.

In one embodiment, film 276 blocks 99.9% of UV light, 60-70% of HEV light, and 30-40% of photosensitivity (PS) light. In one embodiment the film 276 comprises a UV-inhibiting polycarbonate substrate with a thickness of at least 5 mils. In one embodiment, the thickness is less than 10 mils. In one embodiment, film 276 also comprises a UV-inhibiting additive, comprising at least 1% of the film 276. In one embodiment, the UV-inhibiting additive comprises at least 2% of the film, but less than 3% of the film 276. In one embodiment, the film 274 also comprises phthalocyanine dye, comprising at least 0.005% of the film 274. In one embodiment, the phthalocyanine dye comprises at least 0.01%, or at least 0.015%, but less than 0.02% of the film 276. In one embodiment, the film 276 comprises a hard coating. In one embodiment, film 276 can also be characterized as having an optical density that is at least 4 in the 280-380 nm range, at least 2 in the 380-390 nm range, at least 0.8 in the 290-400 nm range, at least 0.13 in the 400-600 nm range, and at least 0.15 in the 600-700 nm range.

In one embodiment, film 278 blocks 99% of UV light, 60-70% of HEV light, and 30-40% of PS light. In one embodiment, film 278 comprises a UV-inhibiting PVC film, with a thickness of at least 8 mils. In one embodiment, the thickness is at least 10 mils, or at least 15 mils, but less than 20 mils thick. In one embodiment, film 278 also comprises an elastomer.

In one embodiment, the film is configured to substantially block 99% of ultraviolet light in the 200-315 nm range, 99% of ultraviolet light in the 315-380 nm range, and approximately 10% of PS light (i.e., light around 555 nm). In one embodiment, the film is configured to allow up to 65% of visible light (i.e., light ranging from 380 nm to 780 nm) pass through. In some embodiments, the film may block various quantities of blue light. For example, the film may have a layer that blocks 15% blue light, a layer that blocks 30% blue light, a layer that blocks 60% blue light, or combinations thereof. In one embodiment, film comprises a UV-inhibiting film with a thickness of 7-9 mils.

FIG. 3 depicts a graph illustrating transmission as a function of wavelength for a variety of films that may be useful in one embodiment of the present disclosure. In one embodiment, absorption spectra 300 is associated with a generic stock film manufactured by Nabi. Absorption spectra 302 may be associate with another stock film provided by Nabi. Absorption spectra 304 may be associate with an Armor brand film. Absorption spectra 306 may be associated with film 272, in one embodiment. Absorption spectra 308 may be associated with a film 276, in one embodiment. Absorption spectra 310 may be associated with a film 278, in another embodiment including an elastomer. Absorption spectra 312 may be associated with a film 274, in one embodiment. As shown in FIG. 3, using any of the films 272, 274, 276 or 278 produces a reduction in the absorption spectra produced by a device. For example, absorption spectra 306 shows that a maximum transmissivity in the blue light range is reduced from 1.00 to 0.37, approximately. Thus, applying any of the films 272, 274, 276 or 278 to a device, for example device 202, may result in a reduction of the harmful rays of light in the known wavelength ranges and, therefore, any of the plurality of eye related problems described above.

In one embodiment, application of any one of the films shown in FIG. 3 provides a measurable change in the transmission of light from a device to a user, as shown below in Table 3. Table 3 illustrates a percentage of energy remaining in each wavelength range after passing through the indicated applied film.

TABLE 3 ENERGY REMAINING AFTER FILM APPLICATION Nabi Wavelength care Film Film Film Film (nm) Nabi kit Armor 272 274 276 278 UV 380-400 100% 100% 76%  1%  1%  1% 92% HEV 415-455 100%  93% 88% 90% 79% 64% 33% Blue All 400-500 100%  93% 89% 86% 78% 66% 37% Blue Cyan 500-520 100%  94% 90% 86% 82% 69% 36% Green 520-565 100%  93% 88% 91% 84% 69% 36% Yellow 565-580 100%  93% 88% 92% 82% 68% 33% Orange 580-625 100%  93% 88% 93% 74% 64% 28% Red 625-740 100%  92% 83% 89% 45% 52% 21%

As shown in Table 3 above, any of the films described herein provide a significant reduction in the energy remaining in a plurality of wavelength ranges after filtering between the light produced by a device, for example device 202, and the eye 250. Films 272, 274, 276 and 278 almost completely absorb the UV light emitted by a device 202.

An organic dye impregnated film, such as film 272, 274, 276 or 278 may, in one embodiment be provided in the form of a rectangular shaped, or square shaped piece of film, as shown in FIG. 1C. One or more optical filters of a desired shape may then be cut from the film. As shown in FIG. 1A, for example, one embodiment of an optical film may include a substantially rectangular shape for a smartphone with a circle removed for a button of the smartphone. In another embodiment, an optical filter may include a circle filter design, for example, to cover a digital image sensor in a camera of a cell phone or other electronic device. In a further embodiment, the optical filter is provided either to a manufacturer or user in a sheet such that the manufacturer or user can cut the film to a desired size. In another embodiment, the film is provided with an adhesive backing such that it can be sized for, and then attached, to the desired device.

One or more additional layers of material or coating may also be provided on a film. An additional layer of material may include a hard coating to protect the film, for example, during shipping or use. Transmissivity can be improved by applying certain anti-reflection properties to the film, including at the time of application of any other coatings, including, in one embodiment, a hard coating layer. The film may also, or alternatively, have an antiglare coating applied or a tack coating applied.

According to one method of manufacturing, the organic dye is produced, dispersed in the film material (e.g. polycarbonate, in one embodiment), compounded into pellets, and then extruded into a thin film using techniques generally known to those skilled in the art. The organic dye impregnated film composition may thus be provided in the form of pellets, or in the form of an extruded film that may be provided on a roller and then cut to size depending on a specific application.

Methods for Creating a Light-Absorbing Film

FIG. 4A-4C depict a plurality of methods for generating a light-absorbing film for a device in accordance with one embodiment of the present disclosure. As shown in FIG. 4A, method 400 begins at block 402 wherein a user obtains their device. The device may be a smartphone, laptop, tablet, or other light-emitting device, such as device 102. The user then obtains and applies a film, such as film 100, as shown in block 404. The user may select a film 100 based on a particular eye problem, or the desire to prevent one or more particular eye-related problems. After the user obtains a device, they may apply the film 100, for example, by utilizing an adhesive layer. The adhesive layer may be found on an aftermarket film, such as film 272, 274, 276 or 278.

As shown in FIG. 4B, method 410 illustrates a method for a manufacturer of a device to provide a safer screen to a user, where the safer screen comprises a film with properties such as those described above with respect to films 272, 274, 276 and/or 278. In one embodiment, the method 140 begins at block 420 wherein the manufacturer produces a screen with a combination of one or more absorbing compounds. In one embodiment, the dye may be selected from any of those described above, in order to reduce the transmission of a specific wavelength(s) of light from the device. The manufacturer may produce the screen such that the dyes are impregnated within the screen itself, and are not applied as a separate film to the screen. The method then continues to block 422, where the manufacturer applies the screen to the device, for example using any appropriate mechanism, for example by use of an adhesive. In one embodiment, the method then continues to block 424 wherein the manufacturer provides the device to a user, this may comprise through a sale or other transaction.

FIG. 4C illustrates a method for producing a film with specific absorption characteristics in accordance with an embodiment of the present disclosure. In one embodiment, method 430 starts in block 440 with the selection of wavelengths for the film to absorb, or otherwise inhibit them from reaching the eye of a user. The method then continues to block 442 wherein one or more absorbing compounds are selected in order to absorb the chosen wavelength ranges, for example from Table 1 above. The method then continues to block 444 wherein an appropriate film base is selected. The appropriate film base may be the screen of a device. In another embodiment, the appropriate film base may be one of any series of polymers that is compatible with the chosen dye. In one embodiment, the user may first select an appropriate film, for example based on device characteristics, and then select appropriate dyes, thus reversing the order of blocks 442 and 444.

The method 430 continues in block 446 where the dye impregnated film is produced. In one embodiment, this may involve co-extrusion of the film with a plurality of absorbing compounds. The film may be provided as a series of resin beads and may be mixed with a series of resin beads comprising the absorbing compounds desired. In an alternative embodiment, the absorbing compounds may be provided in a liquid solution. However, any other appropriate mechanism for producing a dye-impregnated film may also be used in block 446. In one embodiment, it may also be desired for the film to have another treatment applied, for example a glare reducing or a privacy screen feature. In another embodiment, the film may be treated to have a hard coating, or may be treated with a tack coating. In one embodiment, any or all of these treatments may be provided in block 448.

In one embodiment, the method continues in block 450 where the film, for example film 100, is provided to the device, for example device 102. As described previously, this may involve the manufacturer applying a screen, such as screen 102, with the desired characteristics to the device 100 using an appropriate manufacturing procedure. It may also comprise providing dye impregnated aftermarket film to a user who then applies the film to the device, for example through either method 400 and 410 described previously.

In one embodiment of a method for generating a light-absorbing film for a device, the film is produced by layering several coatings on top of one another. More specifically the film may be comprised of several layers such as, but not limited to, a matte topcoat, a blue dye layer, a polyethylene terephthalate (hereinafter “PET”) layer, a UV protection layer, a pressure sensitive adhesive (hereinafter “PSA”), and a liner.

In some embodiments, the first layer applied, which is the top layer in the final embodiment, is a matte topcoat. The matte topcoat may provide an anti-glare feature, may be oil-resistant, and may contain anti-fingerprint properties. Additionally, the matte topcoat may block a small amount of high energy visible light, such as blue light. In one embodiment, the matte topcoat contains a haze factor, which describes the cloudiness of the film. Ideally, the haze factor is approximately 3% so as not to impede a user's view of the device's screen. However, the haze factor could range up to 26%. Some embodiments of the disclosed film do not include a matte topcoat and, instead, have no topcoat or have a clear hard coat.

The next layer that may be applied is a blue dye. The blue dye layer may block various quantities of high energy visible light, such as blue light. For example, the blue dye layer may block 30% of blue light and may be cool blue in color. In another example, the blue dye layer may block 60% of blue light and may be blue green in color. The blue dye layer, if added as the first layer, may also incorporate properties that enable it to act as a hard coat. Some embodiments, however, will not contain either of these blue dye layers.

Regardless of whether the blue dye layer is included, the next layer is a PET layer that blocks approximately 15% blue light. Therefore, the film may have a layer that blocks 30% blue light and an additional layer that blocks 15% blue light, or it may be limited to one layer that blocks 15% blue light. The PET layer is preferably clear and contains no color tint. If the film does not have a matte topcoat or a blue dye layer, the PET layer also acts as the topcoat and may incorporate properties that protect the remaining layers.

The next layer, which is added on to the PET layer, is a UV protection layer that can block at least 99% of UV light. The UV protection layer may have any of the features discussed above. On top of the UV layer, a PSA, such as a silicone PSA, may be applied. The adhesive may be configured so that it prevents bubbles from forming between the film and the device during application of the film to the device. In some embodiments, the film may not include an adhesive layer. For example, applying the film to electronic devices with large screens (ex: computer monitors) using an adhesive may not be feasible and, therefore, a different attachment method, such as clips that clip the film to the monitor, is used.

After the adhesive or UV layer is applied, a white paper liner and/or a clear, printable liner may be applied to the top to protect the computer-facing layer, whether the computer-facing layer is the UV layer or the PSA. This prevents the film from attaching to any objects or being exposed to dirt and debris prior to attachment to an electronic device.

In one embodiment, for example when used as a light filter, the organic dye impregnated film allows for targeted transmission cutoff at a particular wavelength, for example proximate the ends of the visible wavelength spectrum. In this application, the curve should further increase the overall transmission of visible wavelengths, for example, red wavelengths. The light filter may improve the true color rendering of digital image sensors, using silicon as a light absorber in one embodiment, by correcting the absorption imbalances at red and blue wavelengths, thereby yielding improved picture quality through improved color definition.

When used as an LCD retardation film, consistent with another embodiment, the organic dye impregnated film provides desired optical properties, such as 0 to 30° or 0 to 26° chief ray of incident angle and selective visible wavelengths at the 50% transmission cutoff, as well as superior mechanical robustness at less than 0.01mm thickness. Fundamentally, pigments tend to stay on the surface, as do some dyes given either the process of applying the dyes or the substrates. The disclosed products embody dye particles throughout the carrying substrate—therefore light that hits the substrate will collide with dye particles somewhere enroute through the substrate. Therefore, the substrate is designed, in one embodiment, to be safe at a minimum incidence angle of 30°. The LCD retardation film may also provide better UV absorbance than other conventional LCD retardation films.

When used as a light emission reducing film, consistent with a further embodiment, the organic dye impregnated film reduces light emissions from an electronic device at certain wavelengths that may be harmful to a user. The light emission reducing film may reduce peaks and slopes of electromagnetic emission (for example, in the blue light range, the green light range and the orange light range) to normalize the emission spectra in the visible range. The emission spectra may be normalized, for example, between 0.0034-0.0038. These optical characteristics may provide the greatest suppression of harmful radiation in the thinnest substrate across the visible and near infrared range, while still meeting the industry standard visible light transmission requirements.

While an LCD display is illustrated in the figures, at least some embodiments of the present disclosure could apply to a device utilizing a different display generation technology, for example cathode ray tube (CRT) or light-emitting diode (LED) displays.

Incorporation into Electronic Device

As described above, in some embodiments, the protective film comprises a combination of polymer substrates and incorporates absorbing compounds in such quantities as to absorb the harmful light produced by the device. However, in other embodiments, the absorbing compounds and polymer substrates could be incorporated into the screen layers of a device during manufacture, as illustrated in FIGS. 5C-5F and 5H, such that an electronic device is produced with protection from these harmful rays built in.

The description below is designed to accompany the enclosed FIGS. 5A-5H. However, while the present embodiments are described with respect to a device with touchscreen capability, provided through the capacity grid layer 506, it is to be understood that at least some embodiments of the present disclosure could apply to a device without touch screen capability. Further, while an LCD display is shown in the figures, at least some embodiments of the present disclosure could apply to a device utilizing a different display generation technology. For example, cathode ray tube (CRT) or light-emitting diode (LED) displays are possible.

In one embodiment, as shown in FIGS. 5A and 5B, the screen of an electronic device comprises several layers of glass and/or plastic. These layers may be configured to provide added functionality, for example, touch-screen capability, as well as protection of the device from damage by use. FIGS. 5A and 5B illustrates an exemplary screen of a digital device comprised of five layers: an LCD layer 510, a glass layer 508, a capacity grid layer 506, a flexible protective cover 504, and a surface coating layer 502. The device may be a capacitive device, such as a cellular phone or tablet with a touch-sensitive screen. The device may also be another form of a display device such as, but not limited to, a television with a non-capacitive screen. Additionally, the device may be a form of headgear, such as glasses or contact lenses, worn by a user who is exposed to light.

In one embodiment, as shown in FIGS. 5C and 5D, one or more absorbing compounds can be provided in a polymer layer to create an absorbing film layer 512 that is inserted between one of the layers comprising the screen of an electronic device, for example, the layers previously described with regard to FIGS. 5A and 5B. As shown in FIGS. 5C and 5D, the absorbing film layer 512 could be applied between the LCD layer 510 and the glass layer 508. However, in another embodiment, the absorbing film layer 512 could be applied between the glass layer 508 and the capacity grid layer 506. In another embodiment, the absorbing film layer 512 could be applied between the capacity grid layer 506 and the flexible protective cover 504. In another embodiment, the absorbing film layer 512 could be applied between the flexible protective cover 504 and the surface coating layer 502.

In one embodiment, the absorbing film layer 512 could be applied as a film layer inserted between any of the layers comprising the screen of an electronic device or as a hard coating to any one of the layers comprising the screen of an electronic device. In another embodiment, the absorbing film layer 512 could be applied as a hot coating or as a painted layer.

In a further embodiment, one or more absorbing film layers could be combined with the layers comprising the screen of an electronic device, for example, the layers previously described with regard to FIGS. 5A and 5B. For example, four absorbing film layers 512 could be provided such that they fit between each of the five layers of the screen. However, in another embodiment, two or three absorbing film layers 512 are provided between at least some of the five layers of the screen.

The absorbing film layer 512 can include at least a polymer substrate. In one embodiment, the selected polymer substrate absorbs the desired wavelengths of light. However, in another embodiment, an additional absorbing compound is used for absorption of all of the desired wavelengths of light. In a further embodiment, several absorbing compounds can be combined with a single polymer substrate to achieve the desired protection. FIG. 5G illustrates light waves being emitted from a computer screen. FIG. 5H illustrates the absorbing film layer 512 absorbing and, therefore, blocking those specific light waves from reaching the user. A list of several polymer bases that could be utilized in one embodiment is provided below in Table 4.

TABLE 4 POLYMER BASES FOR ABSORBANCE FILM Polymer base Characteristics Acrylic impact modified, chemical resistance, superb weatherability, UV resistance and transparency Epoxy Resistivity to energy and heat Polyamide Thermoformabilty, abrasion resistance, good mechanical properties; High tensile strength and elastic modulus, impact and crack resistance Polycarbonate Impact strength even at low temperatures. dimensional stability, weather resistance, UV resistance, flame retardant, super-weather resistance and heat stability, optical properties Polyester Optics, mechanical Strength, Solvent Resistant, Tear and puncture resistant Co-polyester printable, scratch hardness (PETG, PCTG) Polyethylene Geomembrane windows, global recylability, good moisture barrier, clarity, strength, toughness Polyolefin Good chemical resistance Polypropylene High impact and puncture resistance, excellent extensibility Polystyrene good printablity, high impact resistance, good dimensional stability, easy to thermoform Polysolfone high strength, amorphous thermoplastic, clarity and toughness, high-heat deflection temperature, excellent thermal stability, excellent hydrolitic stability Polyurethane Excellent laminated transparency, microbial resistance, UV stability, contains adhesion promoter, medium Durometer, Medium Modulus, Excellent Cold impact Polyvinyl Weathering resistance, abrasion resistance, chemical resistance, flow Chloride characteristics, stable electrical properties Styrene superior mechanical strength, chemical resistance, heat resistance, Acrylonitrile durability, simplicity of production, recyclability, impact strength, heat resistance, good impact resistance, excellent hygiene, sanitation and safety benefits.

In one embodiment, one of the polymers selected from Table 4 is combined with one or more absorbing compounds in the desired target range, as illustrated in Table 5 below. The absorbing compounds listed in Table 5 are some examples of absorbing compounds selectable for desired protection in given wavelength ranges.

TABLE 5 ABSORBING MATERIALS AND WAVELENGTH RANGES Exemplary Polymer 260-400 nm 400-700 nm Infrared Substrate Target Range Target Range Target Range Polycarbonate Tinuvin ® ABS 668 NIR1002A PVC DYE VIS 347 ADS640PP NIR1031M Epoxy UVA290A VIS675F NIR1072A Polyester VIS530A DYE VIS 670 Adam Gates IR 1422 Polyethylene ABS 400 ABS 691 Adam Gates IR 1151 Polyamide phthalocyanine LUM690 LUM1000A FHI 6746 LUM995 Moleculum DYE 690

The absorbing film layer 512, in one embodiment, has a slight color tint as a result of, at least in part, the absorbing compound selected, and works as a filter to reduce light emission from the screen. In one embodiment, under a CIE light source D65, the absorbing film layer 512, having a 7.75 mil thickness, is a light blue-green color with (L, a, B) values of (90.24, −12.64, 3.54) and (X-Y-Z) values of (67.14, 76.83, 78.90) respectively. In another embodiment, the absorbing film layer 512 appears light due to reduced loading.

In one embodiment, the polymer substrate and absorbing compound or compounds are mixed and extruded as pellets that can then be molded into the absorbing film layer 512. Alternatively, they can be headed for a hot coat. In another embodiment, the polymer substrate and one or more absorbing compounds are extruded or produced as part of any of the layers of the screen of the device.

In one embodiment, between one or more of each of the layers of a screen of an electronic device, an adhesive compound may be used to ensure that the layers fit together. The adhesive compound may further provide a seal between the layers. Therefore, instead of providing protection from harmful light wavelengths as an additional film layer within the screen, the protection may be provided through the adhesive used to bind the layers of the screen.

FIGS. 5E and 5F illustrate an exemplary screen of a digital device incorporating a light absorbing adhesive 514 that has wavelength-absorbing properties. In one embodiment, as shown in FIGS. 5E and 5F, one or more absorbing compounds are provided in a light absorbing adhesive 514 coating a top or bottom side of the layers previously described with regard to FIGS. 5A and 5B. For example, the light absorbing adhesive 514 could be applied, as shown in FIGS. 5E and 5F, as the adhesive bonding the capacity grid layer 506 to the flexible protective cover 504. However, in another embodiment, the light absorbing adhesive 514 could be applied as the adhesive bonding the LCD layer 510 to the glass layer 508. In another embodiment, the light absorbing adhesive 514 could be applied as the adhesive bonding the glass layer 508 to the capacity grid layer 506. In another embodiment, the light absorbing adhesive 514 could be applied such that it bonds the flexible protective cover 504 to the surface coating layer 502.

In a further embodiment, one or more absorbing compounds could be used as part of the adhesive bonding between each of the five layers. For example, the light absorbing adhesive 514 could be the sole adhesive used between the five layers. However, in another embodiment, the light absorbing adhesive 514 can be used between two or three of the layers of the screen. In one embodiment, the absorbing compound selected is based on a selected range of light wavelengths to block. For example, the absorbing compound selected may be from any of the columns 2-4 of Table 5.

The light absorbing adhesive 514 can include at least a polymer substrate. In one embodiment, the selected polymer substrate absorbs the desired wavelengths of light. However, in another embodiment, an additional absorbing compound is used for absorption of all of the desired wavelengths of light. In a further embodiment, several absorbing compounds can be combined with a single polymer substrate to achieve the desired protection.

In one embodiment, a silicone adhesive can be used with any of the absorbing compounds listed in columns 2-4 of Table 5. In one embodiment, a pressure-sensitive adhesive can be used with any of the absorbing compounds listed in columns 2-4 of Table 5. In another embodiment, a hot melt adhesive can be used with any of the absorbing compounds listed in columns 2-4 of Table 5. In a further embodiment, an acrylic adhesive can be used with any of the absorbing compound listed in columns 2-4 of Table 5.

In one embodiment, dissolving the desired absorbing compound in a ketone-based solvent, preferably a methyl-ethyl-ketone, can create the adhesive. The dissolved absorbing compound can then be missed with the desired adhesive compound. For example, in one embodiment, a pressure-sensitive adhesive can be combined with an absorbing compound dissolved in a ketone-based solvent. In at least one embodiment, the method includes at least one filtering step to remove un-dissolved absorbing compounds. In another embodiment, the method includes the addition of extra solvent to re-dissolve absorbing compounds causing caking along the process. An adhesive layer, in one embodiment, has a slight color tint, as a result of, at least in part, the absorbing compound selected, and works as a filter to reduce light emission from the screen. In one embodiment, under a CIE light source D65, the adhesive layer, having a 7.75 mil thickness, is a light blue-green color with (L, a, B) values of (90.24, −12.64, 3.54) and (X-Y-Z) values of (67.14, 76.83, 78.90) respectively. In another embodiment, the adhesive layer appears lighter due to reduced loading.

In some embodiments, the absorbing compounds can be provided in one or more polymer substrates to be integrated with the electronic screen's polarizing filter. For example, in the case of an electronic screen with an LCD screen, the screen has two polarizing filters and the absorbing compounds can be coated over one of the screen's polarizing filters. In the case of a coating, the absorbing compounds can be provided in a polymer substrate that enables the polarizer filter to be laminated with the absorbing compounds. In another example, the absorbing compounds can be incorporated directly into one of the two polarizing filters.

As described above, the absorbing compounds ideally block only a portion of the wavelength ranges for each color, so that each hue is still visible to the individual viewing the screen of the electronic device. Therefore, in embodiments wherein the absorbing compounds are integrated into an electronic devices screen, colors that have portions of their wavelengths blocked by the disclosed technology can be amped up so that the small range allowed through the absorbing compounds is brighter.

Incorporation into Virtual Reality Headset

While other embodiments have been described with respect to a device with touchscreen capability provided through the capacity grid, it is to be understood that at least some embodiments of the present disclosure could apply to a device without touch screen capability. For example, in one embodiment, the present disclosure could be applied to, or integrated into, a virtual reality headset device, as illustrated in FIGS. 6A-6C, or another type of head-mounted glass device configured to absorb wavelengths of light generated by a light source.

Virtual reality (VR) headsets are pieces of headgear that users can wear over their eyes for an immersive audiovisual experience. More specifically, VR headsets provide a screen that is inches away from a user's face. Additionally, VR headsets shield ambient light and prevent it from intruding into the user's field of vision. Due to the proximity of screens, and therefore UV and blue light, to users' eyes, VR headsets present unique sets of risks to users. The disclosed technology is uniquely useful with VR headsets because it can block these harmful wavelengths. In some embodiments, because a VR headset blocks ambient light from interfering with the screen, the pigmentation or chemical structure used in the light absorbent material may interfere with the user's color experience and, therefore, the light absorbing materials used for a VR headset may vary from the above-described embodiments.

Some virtual reality headsets include glasses, frames, or units combined with headphones or another listening device and can receive a mobile phone that acts as the screen. The phone can snap into the headset and a user can utilize a mobile application on the phone, as described in U.S. Pat. 8,957,835 (the '835 patent). FIG. 4 of the '835 patent illustrates one type of phone-based virtual reality headset. The present disclosure could be used in conjunction with this virtual reality headset, as illustrated in FIG. 6A. In this embodiment, the light-absorbing layer 602 can be built into the frame of the virtual reality headset in front of the phone so that, when the light is transmitted from the phone, it must pass through the light-absorbing layer 602 before proceeding through the rest of the headset and on to the user's eyes. The light-absorbing layer 602 can embody any of the several properties described above.

Instead of using a phone as a screen, other virtual reality headsets have a built in screen panel. For example, the Oculus Rift, developed by Oculus VR, uses an organic light-emitting diode (OLED) panel for each eye. In these virtual reality headsets, the light-absorbing layer 602 can be included in front of the light display panel, as illustrated in FIGS. 6B and 6C. The light-absorbing layer 602 may be one continuous layer that covers both eyes. In another embodiment, there may be two light-absorbing layers 602, one for each eye. In some embodiments, each light-absorbing layer 602 is a flat panel. In other embodiments, each light-absorbing layer 602 is curved around the interior of the headset.

Display System

FIG. 7 is a schematic cross-sectional view of an example display system 700 with which systems of the present disclosure may be beneficially employed. Such a display system 700 may be used, for example, in a liquid crystal display (LCD) monitor, LCD-TV, handheld, tablet, laptop, or other computing device. Display system 700 of FIG. 7 is merely exemplary, however, and the systems of the present disclosure are not limited to use with systems like or similar to system 700. The systems of the present disclosure may be beneficially employed in other varieties of displays systems that do not necessarily include liquid crystal display technology.

The display system 700 can include a liquid crystal (LC) panel 750 and an illumination assembly 701 positioned to provide illumination light to the LC panel 750. The LC panel 750 typically includes a layer of LC 752 disposed between panel plates 754. Plates 754 can include electrode structures and alignment layers on their inner surfaces for controlling the orientation of the liquid crystals in the LC layer 752. These electrode structures can be arranged so as to define LC panel pixels. A color filter can also be included with one or more of the plates 752 for imposing color on the image displayed by the LC panel 750.

The LC panel 750 can be positioned between an upper absorbing polarizer 756 and a lower absorbing polarizer 758. The absorbing polarizers 756, 758 and the LC panel 750 in combination can control the transmission of light from the illumination assembly 701 to a viewer, the viewer generally being positioned toward the top of FIG. 7 and looking generally downward (relative to FIG. 7) at display system 700. A controller 704 can selectively activate pixels of the LC layer 752 to form an image seen by the viewer.

One or more optional layers 757, can be provided over the upper absorbing polarizer 756, for example, to provide optical function and/or mechanical and/or environmental protection to the display.

The illumination assembly 701 can include a backlight 708 and one or more light management films 740 positioned between the backlight 708 and the LC panel 750. The backlight 708 of the display system 700 can include a number of light sources 712 that generate the light that illuminates the LC panel 750. Light sources 712 can include any suitable lighting technology. In some embodiments, light sources 712 can be light-emitting diodes (LEDs), and more particularly, can be white LEDs. Backlight 708 as illustrated can be a “direct-lit” backlight in which an array of light sources 712 are located behind the LC panel 750 substantially across much or all of the panel's area. Backlight 708 as illustrated is merely schematic, however, and many other other backlight configurations are possible. Some display systems, for example, can include a “side-lit” backlight with light sources (such as LEDs) located at one or more sides of a light-guide that can distribute the light from the light sources substantially across much or all of the area of LC panel 750.

In some embodiments, the backlight 708 emits generally white light, and the LC panel 750 is combined with a color filter matrix to form groups of multicolored pixels so that the displayed image is polychromatic.

The backlight 708 may also include a reflective substrate 702 for reflecting light from the light sources 712 propagating in a direction away from the LC panel 750. The reflective substrate 702 may also be useful for recycling light within the display system 700.

An arrangement 740 of light management films, which may also be referred to as a film stack, a backlight film stack, or a light management unit, can be positioned between the backlight 708 and the LC panel 750. The light management films 740 can affect the illumination light propagating from the backlight 708 so as to improve the operation of the display system 700. The light management unit 740 need not necessarily include all components as illustrated and described herein.

The arrangement 740 of light management films can include a diffuser 720. The diffuser 720 can diffuse the light received from the light sources 712, which can result in increased uniformity of the illumination light incident on the LC panel 750. The diffuser layer 720 may be any suitable diffuser film or plate.

The light management unit 740 can include a reflective polarizer 742. The light sources 712 typically produce unpolarized light, but the lower absorbing polarizer 758 only transmits a single polarization state; therefore, about half of the light generated by the light sources 712 is not transmitted through to the LC layer 752. The reflective polarizer 742, however, may be used to reflect the light that would otherwise be absorbed in the lower absorbing polarizer 758. Consequently, this light may be recycled by reflection between the reflective polarizer 742 and underlying display components, including the reflective substrate 702. At least some of the light reflected by the reflective polarizer 742 may be depolarized and subsequently returned to the reflective polarizer 742 in a polarization state that is transmitted through the reflective polarizer 742 and the lower absorbing polarizer 758 to the LC layer 752. In this manner, the reflective polarizer 742 can be used to increase the fraction of light emitted by the light sources 712 that reaches the LC layer 752, thereby providing a brighter display output. Any suitable type of reflective polarizer may be used for the reflective polarizer 742.

In some embodiments, a polarization control layer 744 can be provided between the diffuser plate 720 and the reflective polarizer 742. The polarization control layer 744 can be used to change the polarization of light that is reflected from the reflective polarizer 742 so that an increased fraction of the recycled light is transmitted through the reflective polarizer 742.

The arrangement 740 of light management films can also include one or more brightness enhancing layers. A brightness enhancing layer can include a surface structure that redirects off-axis light in a direction closer to the axis of the display. This can increase the amount of light propagating on-axis through the LC layer 752, thus increasing the brightness of the image seen by the viewer. One example of a brightness enhancing layer is a prismatic brightness enhancing layer, which has a number of prismatic ridges that redirect the illumination light through refraction and reflection. Examples of prismatic brightness enhancing layers include BEF prismatic films available from 3M Company. Other varieties of brightness enhancing layers can incorporate non-prismatic structures.

The exemplary embodiment illustrated in FIG. 7 shows a first brightness enhancing layer 746 a disposed between the reflective polarizer 742 and the LC panel 750. A prismatic brightness enhancing layer typically provides optical gain in one dimension. An optional second brightness enhancing layer 746 b may also be included in the arrangement 740 of light management layers, having its prismatic structure oriented orthogonally to the prismatic structure of the first brightness enhancing layer 746 a. Such a configuration provides an increase in the optical gain of the display system 700 in two dimensions. In other exemplary embodiments, the brightness enhancing layers 746 a, 746 b may be positioned between the backlight 708 and the reflective polarizer 742.

The different layers in the light management unit 740 can be free standing. In other embodiments, two or more of the layers in the light management unit 740 may be laminated together. In other exemplary embodiments, the light management unit 740 may include two or more subassemblies.

It is to be understood that as a schematic diagram, the components of display system 700 are not illustrated to scale, and generally are shown with greatly exaggerated thickness (along the up-down direction of FIG. 7) compared to their lateral extent (along the left-right direction). Many elements of display system 700, including (but not necessarily limited to) 702, 720, 742, 744, 746 a, 746 b, 752, 754, 756, and 757 can extend in two dimensions generally orthogonal to their thickness (i.e., perpendicular to the plane of FIG. 7) over an area approximately equal to a viewable area of the display, which may be referred to as a “display area.”

Returning to backlight 708, in some embodiments light sources 712 can emit significant amounts of light in potentially harmful wavelength ranges, such as UV and blue light ranges (particularly below about 455 nm). In a display system 700 that does not include systems of the present disclosure, significant amounts of such potentially harmful light can be emitted by the display system 700 toward a user (upward relative to FIG. 7). In this context a “significant” amount of light can mean an amount of light that may result in deleterious health effects for a display user. In view of this hazard, the present disclosure provides systems for reducing the amount of harmful blue light emitted from display systems such as system 700.

In some approaches to mitigating the hazards of blue light emissions from electronic device displays, absorbing materials can be used to reduce the amount of light in particular wavelength ranges (such as UV and blue light wavelength ranges) that reach users' eyes. Some of these solutions are described in U.S. Nonprovisional application Ser. No. 14/719,604, filed May 22, 2015 and titled LIGHT EMISSION REDUCING FILM FOR ELECTRONIC DEVICES, U.S. Provisional Application No. 62/002,412, filed May 23, 2014 and titled LIGHT EMISSION REDUCING FILM FOR ELECTRONIC DEVICES, U.S. Provisional Application No. 62/175,926, filed Jun. 15, 2015 and titled LIGHT EMISSION REDUCING FILM FOR ELECTRONIC DEVICES, U.S. Provisional Application No. 62/254,871, filed Nov. 13, 2015 and titled LIGHT EMISSION REDUCING COMPOUNDS FOR ELECTRONIC DEVICES, U.S. Provisional Application No. 62/255,287, filed Nov. 13, 2015 and titled LIGHT EMISSION REDUCING FILM FOR VIRTUAL REALITY HEADSET, U.S. Provisional Application No. 62/322,624, filed Apr. 14, 2016 and titled LIGHT EMISSION REDUCING FILM FOR ELECTRONIC DEVICES, U.S. Provisional Application No. 62/421,578, filed Nov. 14, 2016 and titled LIGHT EMISSION REDUCING COMPOUNDS FOR ELECTRONIC DEVICES, International Application under the Patent Cooperation Treaty No. PCT/US2015/032175, filed May 22, 2015 and titled LIGHT EMISSION REDUCING FILM FOR ELECTRONIC DEVICES, and International Application under the Patent Cooperation Treaty No. PCT/US2016/037457, filed Jun. 14, 2016 and titled LIGHT EMISSION REDUCING COMPOUNDS FOR ELECTRONIC DEVICES, which are incorporated by reference limited such that no subject matter is incorporated that is contrary to the explicit disclosure herein.

Incorporation of Light Absorbing Materials into Display Systems

In some embodiments of systems of the present disclosure, light absorbing materials can be located in any suitable location away from light sources of the display. In some embodiments, light absorbing materials can be included in, on, or with one or more films of light management films 740, and or another film or films not illustrated in FIG. 7. In general, light absorbing materials can re-emit light with different directionality and/or polarization compared with light absorbed by the light absorbing materials. Accordingly, in some embodiments light absorbing materials can be included below (relative to the orientation of FIG. 7) one or more of reflective polarizer 742 and/or brightness enhancement layers 746 a, 746 b, such that re-emitted light passes through films 742, 746 a, and 746 b (if such films are present in the display system) before exiting the display toward a user. However, this is not limiting and light absorbing materials potentially can be located in, or, or with any component of light management films 740.

In some embodiments of systems of the present disclosure, light absorbing materials can be included in, on, or with a display layer between LC layer 752 and a user, such as layer 757 of FIG. 7.

In some embodiments of systems of the present disclosure, light absorbing materials can be included in, on, or with reflective substrate 702.

In some embodiments of systems of the present disclosure, light absorbing materials can be distributed substantially about an entire area corresponding to the display area of a display when included or provided in, on, or with a film of light management films 740, reflector 702, or another layer, such as layer 757. In some such embodiments, light absorbing materials can be distributed substantially uniformly over such an area.

Light absorbing materials can be included or provided in, on, or with a film of light management films 740, reflector 702, or another layer, such as layer 757, in any suitable manner. In some embodiments, light absorbing materials can be extruded or cast with a film, In some embodiments, light absorbing materials can be coated onto a film. In some embodiments, light absorbing materials can be provided in or with an adhesive used to bond or laminate one or more layers of a display system, such as any suitable layers or films of display system 700. Such an adhesive incorporating light absorbing materials can be substantially optically clear, exhibiting negligible scattering of light transmitted through the adhesive, other than redirection of light associated with absorption and re-emission by light absorbing materials.

In some embodiments, light absorbing materials can be solubly or insolubly distributed or dispersed throughout a material that is a component or precursor of any suitable film or layer of display system 700, such as a polymer resin or an adhesive. In some embodiments, light absorbing materials can comprise nano-particles, some which may be insoluble in polymers and commonly used solvents. While homogeneous distribution may be more easily achieved in some systems with soluble light absorbing materials, even heterogeneous distribution can be achieved with insoluble light absorbing materials with appropriate handling during manufacture.

Retina Protection Factor (RPF)

Blue Light or high energy visible light is recognized by a number of sources as potentially harmful to eye health. The toxicity of this Blue Light Hazard as outlined in the ICNIRP guidelines published in Health Physics 105(1): 74-96; 2013, has been adopted in the ANSI Z80.3 and CE-166 Standards, and is summarized below in Table 6.

TABLE 6 nm *BLH-ANSI Z80.3 Table far UV 200-315 0 Near UV 315-380 0 380 0.006 385 0.012 390 0.03 395 0.05 400 0.1 405 0.2 410 0.4 415 0.8 420 0.9 425 0.95 430 0.98 **Peak 435 1 **Peak 440 1 445 0.97 450 0.94 455 0.9 460 0.8 465 0.7 470 0.62 475 0.55 480 0.45 485 0.4 490 0.22 495 0.16 500 0.1 (*BLH = Blue light Hazard ANSI = American National Standards)

The RPF (retina protection factor) value is based on the percent reduction due to the use of a selective filtering of the most toxic wave lengths of Blue Light as outlined in table 6 above for the Blue Light Hazard, BLH. The luminance vs. wave-length of a light source is calculated using a spectrophotometer. Those emissions are then multiplied by the factors for toxicity in the table above. The sum of those values over the range of the visible spectrum is then the weighted toxicity level for that light source according to the following equation with definitions:

Total Blue Light Hazard=Σ L(λ)×BLH(λ)×(Δλ)

-   BLH(λ). The Blue light hazard toxicity weighting function in Table 6     above. -   L(λ)=Luminance or Emission for the monitor in candela/meter squared -   (Δλ)=the bandwidth over which the toxicity rating is associated (5     nm)

A candidate film is then applied to the light source (display) and the measurement and the toxicity of the light is again calculated by the same procedure. The reduction of the toxicity is then expressed as a % reduction

(100×[Toxicity without film−Toxicity with film]/Toxicity without film)=(x) % Reduction=RPF(x)

436 Dye−Low, Med and High Concentration−Spectral Scan, RPF Value, Change in Luminance, Gamut, RGB Location change and delta E's

Display manufacturers, when specifying a blue light reduction film, may wish to balance the reduction in Blue Light Toxicity with minimizing the impact on color and luminance of their particular display.

Notch Absorbers and Multiple-Notch Filters

Some embodiments described herein make use of “notch” absorbing dyes that minimize negative impacts on color and luminance while more specifically targeting particular hazardous wave-lengths for blue light. “Notch” absorbers for the purpose of this technology can be defined as absorbers with an absorption band width of 50 nm or less at their respective full width half maximum (FWHM). In some examples, a notch can have a FWHM of less than about 40 nm, less than about 30 nm, less than about 20 nm, and/or less than about 10 nm. While examples herein may describe the use of notch absorption dyes, it should be recognized that other light filtering mechanisms other than absorptive dyes can be used to filter light in particular wavelength ranges, including notch bands. For example, multi-layer interference filters can be precisely tailored to affect narrow wavelength ranges.

In this disclosure, we describe concepts for double-notch filters for electronic devices that filter light from both the blue spectrum as well as the red spectrum. Either or both absorption regions can achieved with absorption dyes, but the concept is not limited to such absorption dyes. Any examples specifically employing a particular technology or combination of technologies (for example, absorptive dyes in two regions) can be generalized to include any combination of light filtration technologies capable of effecting the same net resultant filtration.

One reason for adding red light filtration/absorption to a filter is that a single notch blue filtering/absorbing filter, by removing blue light, can cause the resulting filtered light to shift to a lower color temperature (compared to the spectrum of light input to the filter). This can be undesirable for at least color management reasons. By also removing a narrow-band portion of light in a red part of the spectrum, the color temperature can be shifted back to a higher value, which may be more desirable for color management.

In some examples, a double-notch filter can, using input light from a conventional LED-backlit LCD display, output light that can be measured as substantially satisfying criteria for a D65 white point. In some examples, a double-notch filter can output light that can be measured as nearly satisfying criteria for a D65 white point, to within +/− 500 Kelvin. In some examples, a double-notch filter can output light that can be measured as nearly satisfying criteria for a D65 white point, to within +/− 1000 Kelvin.

FIG. 8 shows spectra for changing concentrations of a narrow notch blue light filtering dye of the present disclosure.

Table 7 illustrates how balance can be achieved when filtering blue light and shows how changes in concentration impact RPF value and change in color temperature, CCT. The second half of the table (the second set of three rows) shows the use of a red-absorbing “color correction dye” (a notch absorption dye with a peak absorption at about 630 nm) to reduce the absolute change from 999 to 47, while the concentration of blue absorbing dye is held constant. This can be balanced by the changes in correlated color temperature (CCT), luminance, and White Point color (as measured by Delta E) that are considered acceptable (by, for example, manufacturers, users, and any other interested parties). FIG. 9 illustrates the effects of varying concentrations of color correction dye with blue-light absorbing dye concentration held constant, corresponding to the last three rows of Table 7.

TABLE 7 RPF and Color Impact of Dye concentration. RPF Ratio of Value % Change Color (Blue Change in in Concentration correction Light color Luminance of blue light dye to % of weighted temperature cd/m2 Delta Base Film absorbing dye Blue-light “blue” by (from (from E(2000) % Change (arbitrary absorbing light toxicity oringinal original for White in units) dye reduced level) ~6825K) 298 Point Luminance 1 0 57% 61% −1921 −14.4% 3.86 −13.40% 0.25 0 32% 33% −999 −13.8% 1.76 −13.40% 0.0625 0 20% 20% −389 −13.4% 0.7 −13.40% 0.25 2:1 32% 34% 47 −19.5% 2.59 −13.40% 0.25 1:1 32% 34% −424 −16.8% 2.2 −13.40% 0.25 1:2 32% 34% −695 −15.4% 1.98 −13.40%

For comparative purposes, FIG. 10 illustrates impact of a broad-band (not narrow notch) blue-light absorbing dye, without use of a color correction dye. Table 8 shows a comparison of the “notch” dye and the broader absorption dye on the RPF and Color Criteria. The benefit of the narrow notch dye is most significant with higher RPF protection values as well as higher transmission film. At the highest levels of protection and with higher transmission film, there is a 50% greater loss of luminance (15% for the broader absorber vs. 10% for the narrow notch dye).

TABLE 8 Comparison with “Notch” and broader absorption dyes on RPF and Color Impact of Dye concentration. Change in % Change in RPF Value color Luminance Base Concentration % of (Blue Light temperature cd/m2 Film % of blue light “blue” weighted (from (from Change absorbing light by toxicity oringinal original in dye reduced level) 6826K) 298 Luminance UV Narrow 1 57% 61% −1921 −14.4% −13.40% Absorber Notch 0.25 32% 33% −999 −13.8% −13.40% Film Blue Light 0.0625 20% 20% −389 −13.4% −13.40% Absorber Broad 0.91 61% 60% −2207 −18.8% −13.40% Blue Light 0.25 31% 31% −1012 −15.1% −13.40% Absorber 0.667 20% 20% −405 −13.8% −13.40% Higher Narrow 1 56% 61% −1978 −10.1%  −9.06% Trans. Notch 0.25 28% 30% −992  −9.4%  −9.06% Base Blue Light 0.625 18% 16% −381  −9.1%  −9.06% Film Absorber Broad 0.91 61% 61% −2302 −15.1%  −9.06% Blue Light 0.25 31% 31% −1177 −11.1%  −9.06% Absorber 0.667 16% 16% −396  −9.4%  −9.06%

The dye concentration(s) can be adjusted based on a change in the base film (substrate) for incorporation of the dye or the coating containing the dye.

TABLE 9 Illustrates optimization when using different films with different transmission levels. Ratio of RPF Color Value % correction temperature Change in Change light Light color in Delta dye to % of weighted Luminance cd/m2 E(2000) Base Film Concentration Blue-light “blue” by (from (from for % Change of blue light absorbing (Blue toxicity oringinal original White in absorbing dye dye reduced level) ~6825K) 298 Point Luminance 0.25 2:1 32% 34% 47 −19.5% 2.59 −13.40% 0.25 1:1 32% 34% −424 −16.8% 2.2 −13.40% 0.25 1:2 32% 34% −695 −15.4% 1.98 −13.40% 0.25 0 32% 33% −999 −13.8% 1.76 −13.40% 0.25 2:1 28% 30% 55 −15.4% 2.66  −9.06% 0.25 1:1 28% 30% −416 −12.7% 2.26  −9.06% 0.25 1:2 28% 30% −689 −11.1% 2.02  −9.06% 0.25 0 28% 30% −992  −9.4% 1.87  −9.06%

The dye concentrations for both the “notch” dye as well as the color correction dye can be adjusted for optimum performance based on the particular display and the LED's used in the back-light. Table 10 demonstrates two different scenarios. FIG. 11 shows the optimization done for LED Back-light “B” similar to that shown in FIG. 9.

TABLE 10 Demonstrates need to optimize the film parameters based on back-light emission of the display. Change in RPF color Ratio of Value temperature % Change Color (Blue (from in correction Lighted oringinal Luminance Delta dye to % of weighted ~6825K and cd/m2 E(2000) Base Concentration Blue-light “blue” by ~6900K for (from for Film % of blue light absorbing light toxicity A and B original White Change in absorbing dye dye reduced level) respectively) 298 Point Luminance LED 0.25 2:1 32% 34% 47 −19.5% 2.59 −13.40% Back- 0.25 1:1 32% 34% −424 −16.8% 2.2 −13.40% light 0.25 1:2 32% 34% −695 −15.4% 1.98 −13.40% A 0.25 0 32% 33% −999 −13.8% 1.76 −13.40% LED 0.33 1:1 28% 30% 1026 −21.0% 3.37 −13.40% Back- 0.33 1:2 28% 30% 134 −17.9% 2.55 −13.40% light 0.33 1:4 28% 30% −357 −16.0% 2.08 −13.40% B 0.33 0 28% 30% −876 −13.7% 1.67 −13.40%

While the principles of the invention have been described herein, it is to be understood by those skilled in the art that this description is made only by way of example and not as a limitation as to the scope of the invention. Other embodiments are contemplated within the scope of the present disclosure in addition to the exemplary embodiments shown and described herein. Modifications and substitutions by one of ordinary skill in the art are considered to be within the scope of the present disclosure. 

What is claimed is:
 1. (canceled)
 2. A light-filtering film for a screen of a device comprising: a polymer substrate; a first absorbing compound combined with the polymer substrate, the first absorbing compound absorbing blue light in a blue notch band having a full-width half-maximum of not greater than about 50 nm; a second absorbing compound combined with the polymer substrate, the second absorbing compound absorbing red light in a red notch band having a full-width half-maximum of not greater than about 50 nm, wherein the light-filtering film can be used to reduce light emission passing therethrough over a broad spectrum range of from about 200 nm to about 3000 nm.
 3. A light-filtering film for a screen of a device according to claim 2, wherein the absorbing compounds are incorporated into a layer of the device.
 4. A light-filtering film for a screen of a device according to claim 3, wherein the device comprises a pair of glasses or a contact lens.
 5. A light-filtering film for a screen of a device according to claim 2 comprising a coating disposed directly upon the polymer substrate.
 6. A light-filtering film for a screen of a device according to claim 5, wherein the coating comprises an antiglare coating, a hard coating, or a tack coating.
 7. A light-filtering film for a screen of a device according to claim 2, wherein the film reduces light emissions from an electronic device at wavelengths that may be harmful to a user.
 8. A light-filtering film for a screen of a device according to claim 7, wherein the light emission intensity is normalized to a maximum absorbance level between 0.0035 and 0.0038.
 9. A light-filtering film for a screen of a device according to claim 7, wherein the film has a retina protection factor value (RPF) that selectively reduces the total blue light hazard by at least 10%.
 10. A light-filtering film for a screen of a device according to claim 2, wherein the film has a dielectric constant of less and 4 or between 2.2 and 2.5.
 11. A light-filtering film for a screen of a device according to claim 2, wherein the film has polarizing properties that can be used to control the amount of light transmitted through the film.
 12. A light-filtering film for a screen of a device according to claim 2, wherein the films can modify backlit light on electronic devices.
 13. A light-filtering film for a screen of a device according to claim 12, wherein the films modify backlit light in the blue spectral range.
 14. A light-filtering film for a screen of a device according to claim 2, wherein the films comprise a prismatic brightness enhancing layer.
 15. A light-filtering film for a screen of a device according to claim 2, wherein the film further comprises a pressure-sensitive adhesive disposed upon the film.
 16. A light-filtering film for a screen of a device comprising: a polymer substrate; a first absorbing compound combined with the polymer substrate, the first absorbing compound absorbing blue light in a blue notch band having a full-width half-maximum of not greater than about 50 nm; a second absorbing compound combined with the polymer substrate, the second absorbing compound absorbing red light in a red notch band having a full-width half-maximum of not greater than about 50 nm, wherein the light-filtering film can be used to reduce light emission passing therethrough over a broad spectrum range of from about 10 nm to about 350 nm. 